DOCSLIB.ORG

The Techedsat/Phonesat Missions for Small Payload Quick Return

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Techedsat/Phonesat Missions for Small Payload Quick Return TechEdSat 5 / PhoneSat 5 (T5/P5) SmallSat Presentation 2016 TechEdSat-1 TechEdSat-2 TechEdSat-3 TechEdSat-4 SOAREX-8 M.Murbach, R. Alena, A. Guarneros Luna C. Priscal, R. Shimmin J. Wheless, F. Tanner, R. Morrison, K. Oyadomari P. Papadopoulos/SJSU, D. Atkinson/UofIdaho TES/PSAT-Team NASA Ames Research Center Relevant Flight Experiments TES-N First US 3U Nanosat Evolution of TES-3 WSM1, AIM deployed off ISS First Iridium modem Camera Exo-Brake test Uplink/via email X-Band, ISM- demonstrated Band, P5 alpha, Exo-Brake II ISM-Camera and WSM2, AIM Full ExoBrake Camera ISM-Band, P5 alpha, ISM- Camera Modulated Exo-Brake SOAREX-6 TES-1 Improved positional/ 2008 Oct 4, 2012 TES-2 TES-3 target accuracy Iridium test Improved Targeting, Aug 3, 2013 WSM2, ISM Band First US Aug 21, 2013 Nanosat (6 wk deployed off deorbit) ISS First Iridium in- space TES-4 SOAREX-7 PSRP COM process Mar 3, 2015 2009 demonstration mastered (4 wk deorbit) Rad-tolerant processor SOAREX- demo 8 During test SOAREX Recent Years of Flight Experiments (WFF) -9 (WFF) TechEdSat5/ July 7, March 3, PhoneSat5 Coming up (2008-2015): 2015 2016 6 Flights +1(SOAREX8) +PhoneSats 1-4 this year!! …here before SOAREX/TechEdSat-N Team 10/20/13 Relevant Flight Experiments PhoneSat EDSN Super Strypi Oct 29, 2015 Nodes Orb-4 Atlas V Dec 3, 2015 PhoneSat 2.4 Recent Years of Flight ORS-3 Minotaur Experiments 1 (2009-2015) Nov 20, 2013 PhoneSat (still in orbit) SOAREX-9 1a, 1b, 2.0 (WFF) Antares A- March 3, SpaceLoft-6 ONE 2016 Apr 5, 2012 Apr 21, 2013 Balloon SOAREX-8 Intimidator-5 June 9, 2011 Terrier/Black Brant July 29, 2010 July 7, 2015 PhoneSat 2.5 CRS-3 Falcon 9 Apr 18, 2014 PhoneSat Team Status of Analysis TES-3 and TES-4 TES-3/TES-4 Flight Test Data 450 400 350 300 250 TES-3p Altitude (km) Altitude TES-4 200 150 100 0 10 20 30 40 50 60 Satellite Day C.Glass/LaRC [DAC/DSMC] *Active work in progress to refine models based on flight data – including uncertainty analyses (F10.7; geometric variables) - for NASA internal use only - TechEdSat-4 Extruded st Structure • 1 NASA NanoSatellite 3U Solar Design Jettisoned from the NRCSD Panels (TES-3p) (TES-3p) (July 2014) PWR Board • Exo-Brake Demonstration (Improved) • β=8kg/m^2 COM/CNTR Aft-Cover Boards (TES-3p) • Advanced Manufacturing (Improved) Exo-Brake and • COM Experiment III + GPS Iridium/GPS Antenna Deployment System (Improved location; (TES-3p) • Two-tier Architecture TES-3p) RBF Pin (TES-3p) Iridium Antenna #2 Telon Nosecap (TES-3p) Canon BP930 ISS-supplied x2 (TES-3p used 1) Improved Cartridge Design (Ease of integration/test) - for NASA internal use only - T5/P5 Flight System Architecture and Dataflow Ground Segment Space Segment Monitoring and T5/P5 Avionics PWR Subsystem Analysis Iridium Data Solar Panels Applications Distribution 8.4 V Batteries Server Iridium-1 Sensor data stream POWER Board Door and Panel As e-mail Transceiver Actuators Sensor Winch Display and Iridium USB Messaging Analysis Video Stream Applications WSN data Iridium 802.15.4 Pressure Network Crayfish Temp GPS/COMM IMU Sensor Data Display XBee and WSM WSN Status Display Iridium-3 Transceiver Wireless P5 Board Sensor Module WiFi CAM (WSM Gen-2) ISM-band ISM Zigbee sniffer Ground Station 2.4 GHz High-Rate Downlink Camera1 Camera2 TES-5 Science/Mission Objectives -Establish improved uncertainty analysis for eventual controlled flight through the Thermosphere (perform detailed comparison to the TES-3 and TES-4 with respect to key Thermosphere variable uncertainty). -Improve prediction of re-entry location. -Provide the base technology for sample return technology from orbital platforms. -Provide the eventual testing of independent TDRV-based planetary missions -Provide engineering data for an On-Orbit Tracking Device that could improve the TES-5/P-5 Flight Unit prediction of jettisoned material from the (READY to Integrate) ISS (per discussions with the TOPO group). Frequency Coordination TES-1 TES-2 TES-3p TES-4 SOARE SOARE TES-5 X-8 X-9 Iridium N/A 1616-16 1616-16 1616-16 1616-16 1616-16 1616-16 26.5 26.5 16.5 26.5 26.5 26.5 MHz MHz MHz MHz MHz MHz StenSat 437.465 N/A 437.465 N/A N/A N/A N/A MHz MHz ISM N/A N/A N/A N/A 2457 2457 2457 MHz MHz MHz WSM N/A N/A N/A N/A 2410 2410 2410 MHz MHz MHz - for NASA internal use only - De-Orbit/Targeting Interest… Sample Return/Re-entry Targeting With Modulated Exo-Brale: Validation – it WORKS! Entry Landing S. Dutta, A. Cianciolo, R. Powell , (LaRC) Application to larger payloads What is Next? ISS Sample Return SPQR-Small Payload Quick Return • 3 stage concept • On-demand sample return • COM IV experiment • EDL test platform Atromos: Nano-sat Mission to the Surface of Mars • Mission Attributes –local climatology and surface characterization of areas not accessible to large missions (most of Mars!) • Self-stabilizing re-entry probe (TDRV-Tube Deployed Re-Entry Vehicle) • EDL Technique for small probes • Dual probe demonstration 2018-2020 Summary • TES-N/Phone-N series has helped to train ~40 individual now at NASA, SpaceX, Boeing, Lockheed and …Start- ups! • Several ‘Firsts’ for ISS-deployed experiments • Numerous Technologies Advanced • COM [LOW data rate up/downlink – Iridium; MEDIUM and HIGH data rate] ü Commanding the nanosat via EMAIL • Fabrication • De-Orbit Systems (Exo-Brake – MODULATED!) • Evolving 2-tier Architecture ü Arduino/Intel-Edison-Linux based platforms • Pioneered Safety Processes for ISS Satellite Jettison • Future Work leads to ISS Sample Return, Advance Re- entry Development ….. And Mars! .
Load more

Recommended publications
  • Orbital Debris Quarterly News 22-1
    National Aeronautics and Space Administration Orbital Debris Quarterly News Volume 22, Issue 1 February 2018 Inside... Two Anomalous Events in GEO Summer 2017 was marred by two apparently platform. Spacecraft dry mass is estimated to be on Space Debris Sensor anomalous events in the geosynchronous orbit the order of 2000 kg. On-board stored energy sources Launches Aboard (GEO) belt. Both incidents have been observed by include fuel and pressurized components, as well as the commercial space situation awareness providers, but as battery subsystem. SpaceX-13 2 of 26 December 2017 no debris from either event have The Indonesian GEO communications spacecraft entered the public catalog. TELKOM-1 (1999-042A, SSN catalog number 25880) SEM Analysis The GEO communications spacecraft AMC-9 experienced an energetic event on or about 25 August Results of (International Designator 2003-024A, U.S. Strategic 2017, after over 18.1 years on-orbit—3 years past Returned ISS Command [USSTRATCOM] Space Surveillance its nominal operational lifetime. An examination of Network [SSN] catalog number 27820), formerly known the Two Line Element data indicates an observable PMA-2 Cover 4 as GE-12, experienced an energetic event estimated to change in spacecraft orbit between 26 and 29 August. have occurred at approximately 07:10 GMT on 17 June At the beginning of this time interval, approximately CubeSat Study 2017, after approximately 14 years on-orbit. Fig. 1 Project Review 6 depicts the orbital evolution of the spacecraft in 2017. continued on page 2 SES, the spacecraft owner- operator, described this AMC‐9 (SSN 27820, 2003‐024A) 360 36300 Space Debris Sensor event as a “serious anomaly.” Installation 8 Following this event, the 36200 spacecraft began a westward 300 Monthly Object Type drift in the GEO belt.
    [Show full text]
  • A Sample AMS Latex File
    Riot, V. J. et al. (2021): JoSS, Vol. 10, No. 1, pp. 995–1006 (Peer-reviewed article available at www.jossonline.com) www.adeepakpublishing.com www. JoSSonline.com Lessons Learned Using Iridium to Com- municate with a CubeSat in Low Earth Orbit Vincent J. Riot, Lance M. Simms, and Darrell Carter Lawrence Livermore National Laboratory Livermore, CA, USA Abstract This paper presents the design and approval process for operating an Iridium transceiver on orbit and provide on-orbit performance data obtained from a CubeSat platform in Low Earth Orbit (LEO) (500 km orbit). On-orbit data demonstrates that use of a commercial, low-cost Iridium transceiver can serve as a valuable communication approach for low volume telemetry with less than a 30-minute lag for approximately 90% of the time. We also demonstrate that a radial differential velocity of 7 km/sec corresponding to about a 37.5kHz doppler shift and a distance of less than 2,000 km can be used for mission planning. Introduction Setting up a dedicated radio communication link tion is about 5-15 minutes per day per ground station, with a CubeSat in Low Earth Orbit (LEO) presents depending on the altitude and inclination of the satel- several challenges, especially for institutions with lim- lite, as well as the latitude of the ground station. This ited funding or resources. The traditional approach of means the operator is oblivious to the current state of using one or more dedicated radio ground stations to the satellite most of the time, even if multiple ground communicate directly with the satellite is often prohib- stations distributed across the Earth are used.
    [Show full text]
  • Techedsat Satellite Project Techedsat Formal Orbital Debris
    TechEdSat Satellite Project TES-03-XS008 Orbital Debris Assessment Report (ODAR) Rev A TechEdSat Formal Orbital Debris Assessment Report (ODAR) In accordance with NPR 8715.6A, this report is presented as compliance with the required reporting format per NASA-STD-8719.14, APPENDIX A. Report Version: A (4/2/2012) DAS Software Used in This Analysis: DAS v2.0 Page 1 of 34 TechEdSat Satellite Project TES-03-XS008 Orbital Debris Assessment Report (ODAR) Rev A Page 2 of 34 TechEdSat Satellite Project TES-03-XS008 Orbital Debris Assessment Report (ODAR) Rev A Record of Revisions Affected Description of Rev Date Author (s) Pages Change Ali Guarneros Luna, A 4/2/2012 All Initial Release Christopher Hartney, Page 3 of 34 TechEdSat Satellite Project TES-03-XS008 Orbital Debris Assessment Report (ODAR) Rev A Table of Contents Self-assessment and OSMA assessment of the ODAR using the format in Appendix A.2 of NASA-STD-8719.14: Assessment Report Format Mission Description ODAR Section 1: Program Management and Mission Overview ODAR Section 2: Spacecraft Description ODAR Section 3: Assessment of Spacecraft Debris Released during Normal Operations ODAR Section 4: Assessment of Spacecraft Intentional Breakups and Potential for Explosions. ODAR Section 5: Assessment of Spacecraft Potential for On-Orbit Collisions ODAR Section 6: Assessment of Spacecraft Postmission Disposal Plans and Procedures ODAR Section 7: Assessment of Spacecraft Reentry Hazards ODAR Section 8: Assessment for Tether Missions Appendix A: Acronyms Appendix B: Battery Data Sheet Appendix C: Wiring Schematics Page 4 of 34 TechEdSat Satellite Project TES-03-XS008 Orbital Debris Assessment Report (ODAR) Rev A Self­assessment and OSMA assessment of the ODAR using the format in Appendix A.2 of NASA­STD­8719.14: A self assessment is provided below in accordance with the assessment format provided in Appendix A.2 of NASA-STD-8719.14.
    [Show full text]
  • The Annual Compendium of Commercial Space Transportation: 2012
    Federal Aviation Administration The Annual Compendium of Commercial Space Transportation: 2012 February 2013 About FAA About the FAA Office of Commercial Space Transportation The Federal Aviation Administration’s Office of Commercial Space Transportation (FAA AST) licenses and regulates U.S. commercial space launch and reentry activity, as well as the operation of non-federal launch and reentry sites, as authorized by Executive Order 12465 and Title 51 United States Code, Subtitle V, Chapter 509 (formerly the Commercial Space Launch Act). FAA AST’s mission is to ensure public health and safety and the safety of property while protecting the national security and foreign policy interests of the United States during commercial launch and reentry operations. In addition, FAA AST is directed to encourage, facilitate, and promote commercial space launches and reentries. Additional information concerning commercial space transportation can be found on FAA AST’s website: http://www.faa.gov/go/ast Cover art: Phil Smith, The Tauri Group (2013) NOTICE Use of trade names or names of manufacturers in this document does not constitute an official endorsement of such products or manufacturers, either expressed or implied, by the Federal Aviation Administration. • i • Federal Aviation Administration’s Office of Commercial Space Transportation Dear Colleague, 2012 was a very active year for the entire commercial space industry. In addition to all of the dramatic space transportation events, including the first-ever commercial mission flown to and from the International Space Station, the year was also a very busy one from the government’s perspective. It is clear that the level and pace of activity is beginning to increase significantly.
    [Show full text]
  • Phonesat: Modeling a Spacecraft for Remote Imaging
    MIT Space Exploration Initiative Outreach PhoneSat: Modeling a spacecraft for remote imaging Avery Normandin Published on: Apr 02, 2020 License: Creative Commons Attribution 4.0 International License (CC-BY 4.0) MIT Space Exploration Initiative Outreach PhoneSat: Modeling a spacecraft for remote imaging Activity: creating a small satellite to protect your cell phone in outer-space environments! Background: Small satellites are constantly orbiting Earth, providing useful data about the planet over time. These satellites are designed and built by engineers to withstand the harsh space environment. A “cubesat” is a specific type of small satellite that has very particular specifications, making it easier for people around the world to design and launch. Today, you’ll be turning your phone into a mock-satellite! Mission: It’s your first visit to space as NASA’s newest astronaut - congratulations! Your first mission is to deploy a 1U (10 x 10 x 10 cm) small satellite that takes pictures of the plants and trees in your neighborhood. Your plan is to thrust the satellite into orbit by throwing it outside the International Space Station (ISS). However, during launch, you hear a loud crash - the satellite you have spent the last year designing and building has fallen and broken! Mission control informs you that you are still responsible for getting a satellite into orbit upon your arrival to the ISS. Your new mission is to rebuild the satellite and test a prototype first at home -- one that takes. The only ‘computer’ available to run your satellite? Your smartphone! Using the constraints defined by a cubesat, you will be creating a prototype structure that nests your phone as a “satellite payload”.
    [Show full text]
  • Cubesat-Services.Pdf
    Space• Space Station Station Cubesat CubesatDeployment Services Deployment Services NanoRacks Cubesat Deployer (NRCSD) • 51.6 degree inclination, 385-400 KM • Orbit lifetime 8-12 months • Deployment typically 1-3 months after berthing • Soft stowage internal ride several times per year Photo credit: NASA NRCSD • Each NRCSD can deploy up to 6U of CubeSats • 8 NRCSD’s per airlock cycle, for a total of 48U deployment capability • ~2 Air Lock cycles per mission Photo Credit: NanoRacks LLC Photo credit: NASA 2. Launched by ISS visiting vehicle 3. NRCSDs installed by ISS Crew 5. Grapple by JRMS 4. JEM Air Lock depress & slide 6. NRCSDs positioned by JRMS table extension 1. NRCSDs transported in CTBs 7. Deploy 8. JRMS return NRCSD-MPEP stack to slide table; 9. ISS Crew un-install first 8 NRCSDs; repeat Slide table retracts and pressurizes JEM air lock install/deploy for second set of NRCSDs NanoRacks Cubesat Mission (NR-CM 3 ) • Orbital Sciences CRS-1 (Launched Jan. 9, 2014) • Planet Labs Flock1A, 28 Doves • Lithuanian Space Assoc., LitSat-1 • Vilnius University & NPO IEP, LituanicaSat-1 • Nanosatisfi, ArduSat-2 • Southern Stars, SkyCube • University of Peru, UAPSat-1 Photo credit: NASA Mission Highlights Most CubeSats launched Two countries attain in a single mission space-faring status World’s largest remote Kickstarter funding sensing constellation • NR-CM3 • Orbital Science CRS-1, Launch Jan 9, 2014 • Air Lock Cycle 1, Feb 11-15, 2014 Dove CubeSats • Deployers 1-8 (all Planet Labs Doves) Photo credit: NASA • NR-CM3 • Orbital Science CRS-1,
    [Show full text]
  • Communications for the Techedsat/Phonesat Missions NASA Ames Research Center
    Communications for the TechEdSat/PhoneSat Missions NASA Ames Research Center Presentation to Small Satellite Pre-Conference Workshop August 5, 2017 Marcus Murbach, PI Rick Alena, Co-I Ali Guarneros-Luna, Co-I Jon Wheless, Engineer SOAREX/TechEdSat/PhoneSat Teams Flight Experiments of Recent Years (2008-2017): 9 Flights SOAREX-6 (2008) SOAREX-7 TES-1 TES-2 (2009) Oct 4, 2012 TES-3 PhoneSat Aug 3, 2013 Iridium-test (6 wk de- Aug 21, 2013 TES-4 orbit) Mar 3, 2015 TES-5 (4 wk de-orbit) Mar 6, 2017 (deorbited Jul 29) TES/PS Team, 2014 SOAREX-8 (2015) SOAREX-9 (2016) TES/PS Team, Summer 2017 What is an Exo-Brake…? Simple, drag-modulated de-orbit system based on tension elements TechEdSat5 was deployed from ISS on March 6, 2017 by NanoRacks The TechEdSat 5 Exo-Brake Experiment • The Exo-Brake is an exo-atmospheric braking and de-orbit device which has successfully flown twice before in a fixed configuration on TechEdSat-3 and 4 • The TechEdSat rapid prototype flight series is conducted as a hands-on training environment for young professionals and university partners • The project helps verify Entry Systems Modeling by gathering real-world data aboard sounding rockets and CubeSats • In the future, passive Exo-Brake systems may be used for small-sat disposal and the development of technologies to permit on-demand sample return from Low Earth Orbit (LEO) scientific/manufacturing platforms TechEdSat 5 (TES5) Avionics, Software and Communications • The 3.5 U CubeSat contains a low-level AVR microprocessor for power control and a high-level Atom processor for fast data processing • The primary Command and Telemetry (C&T) link is provided by the Iridium constellation through on-board Short Burst Data (SBD) modems.
    [Show full text]
  • 2020 Spring GOES DCS Technical Working Group (TWG) 125 ​ Meeting Th ​ Tuesday, May 5 ,​ 2020 ​ (Virtual Via Webex and Teleconference)
    th 2020 Spring GOES DCS Technical Working Group (TWG) 125 ​ Meeting th ​ Tuesday, May 5 ,​ 2020 ​ (Virtual Via Webex and Teleconference) Opening Remarks/ Introductions – LySanias Broyles (STIWG Chair and U.S. Army Corps of Engineer, Rock Island District) and Richard Antoine (NESDIS/OSPO/SPSD/Direct Services Branch) Richard Antoine opened the meeting at 09:30. DCS Update: 100 BPS Discontinuation, CS2 Status (Richard Antoine (NESDIS/OSPO/SPSD/ Direct Services Branch) Richard began by noting that we now have 659 SUAs and 2,134 registered users. Also noted was that the 100 BPS DCPs are no longer supported as of last January 21, 2020. There has also been an enhancement to DAMS-NT that should result in a better service to users by adding enhanced message statistics and that the site surveys needed to install a backup pilot at the CBU in Fairmont, WB have been accomplished. Letecia Reeves then went over the chart below showing the status of all the DCPs in the system. DCP Status 100 Baud 300 Baud 1200 Baud Totals Active DCPs 0 29,304 520 29,824 Inactive DCPs 0 7,347 604 7,951 Unused DCPs 0 2,400 214 2,614 Totals 0 39,051 1,338 40,389 Note: Statistics do not include the parked channel (-1). Letecia then discussed the factors that determine the status of the DCP. The status levels are in column one, on the left in the table above. They factors are listed in bullet form below: ● A: System received data transmissions w/in 2 days. ● D: No data transmission received in 2 days.
    [Show full text]
  • Phonesat the Smartphone Nanosatellite
    PhoneSat The Smartphone Nanosatellite NASA’s PhoneSat project tests whether To do this, the PhoneSat design makes spacecraft can be built using smartphones extensive use of commercial-off-the-shelf to launch the lowest-cost satellites ever components, including a smartphone. flown in space. Each PhoneSat nanosatellite Smartphones offer a wealth of capabilities is one cubesat unit - a satellite in a 10 cm needed for satellite systems such as fast cube (approx. 4 inches) or about the size of processors, versatile operating systems, a tissue box - and weighs approximately 1 multiple miniature sensors, high-resolution kg (2.2 pounds). Engineers believe PhoneSat technology will enable NASA to launch cameras, GPS receivers, and several radios. multiple new satellites capable of conducting PhoneSat engineers also are changing the science and exploration missions at a small way missions are designed by prototyping fraction of the cost of conventional satellites. and incorporating existing commercial The small teams of NASA engineers technologies and hardware to see what supporting PhoneSat at NASA’s Ames capabilities they can provide, rather than Research Center, Moffett Field, Calif., aim trying to custom-design technology to rapidly evolve satellite architecture and solutions to meet set requirements. incorporate the Silicon Valley approach PhoneSat 1.0 demonstrated that low-cost, of “release early, release often,” adding modern electronics can fly in space. It was new functionality to the satellite with each built around the Nexus One smartphone succeeding iteration. made by HTC Corp., running Google’s Left image: The PhoneSat 1.0 cubesat bus with a smartphone inside. Image credit: Ben Howard.
    [Show full text]
  • The Future of Cubesat Communications
    Upcoming CubeSat Launches: The Flood Has Arrived Bryan Klofas KF6ZEO SRI International [email protected] AMSAT-NA Symposium Houston, Texas 1 November 2013 Upcoming CubeSat Launches Name Vehicle Deployers Date # CS # PQ ORS-3/ELaNa-4 Minotaur 1 8 P-POD/8 NLAS 19 Nov 2013 24 (2 CubeStack) ISS ISS/HTV-4 2 J-SSOD 20 Nov 2013 4 Dnepr Dnepr 9 ISIPOD 21 Nov 2013 18 5 UniSat-5 NROL-39/ELaNa-2 Atlas V 8 P-POD 5 Dec 2013 12 (NPSCuL) ISS ISS/Antares 16 NanoRacks 6U Dec 2013 28+ Soyuz Soyuz 1 ISIPOD Feb 2014 1 Dnepr Dnepr 3 P-POD April 2014 3+ ORS-4 Super Strypi 8 NLAS April 2014 10+ (1 CubeStack) Totals: 100+ 5 Slide 2 Statistics of Upcoming Four Launches • 63 CubeSats and PocketQubs (discussed in paper) – Exact frequencies and services listed if known • 9 satellites using 145 MHz amateur satellite band for downlink – 2 under experimental license (DragonSat-1, CAPE-2) – 7 under amateur satellite service (non-US) • 31 satellites using 437 MHz amateur satellite band for downlink – 23 under experimental license (US) – 8 under amateur-satellite service (non-US) • 4 satellites using 2.2 GHz for downlink • 12 satellites using unpublished frequencies • Remaining 8 satellites using 402, 425, 915, 980 MHz Slide 3 Frequency Licensing • FCC released “Guidance on Obtaining Licenses for Small Satellites” DA-13-445 – Clarifies the licensing process and rules related to small satellites – Does not provide guidance on which service to use • Separately, the FCC is pushing non-amateur CubeSats to file for experimental licenses, even if they are using amateur frequencies
    [Show full text]
  • Prototype Design and Mission Analysis for a Small Satellite Exploiting Environmental Disturbances for Attitude Stabilization
    Calhoun: The NPS Institutional Archive Theses and Dissertations Thesis and Dissertation Collection 2016-03 Prototype design and mission analysis for a small satellite exploiting environmental disturbances for attitude stabilization Polat, Halis C. Monterey, California: Naval Postgraduate School http://hdl.handle.net/10945/48578 NAVAL POSTGRADUATE SCHOOL MONTEREY, CALIFORNIA THESIS PROTOTYPE DESIGN AND MISSION ANALYSIS FOR A SMALL SATELLITE EXPLOITING ENVIRONMENTAL DISTURBANCES FOR ATTITUDE STABILIZATION by Halis C. Polat March 2016 Thesis Advisor: Marcello Romano Co-Advisor: Stephen Tackett Approved for public release; distribution is unlimited THIS PAGE INTENTIONALLY LEFT BLANK REPORT DOCUMENTATION PAGE Form Approved OMB No. 0704–0188 Public reporting burden for this collection of information is estimated to average 1 hour per response, including the time for reviewing instruction, searching existing data sources, gathering and maintaining the data needed, and completing and reviewing the collection of information. Send comments regarding this burden estimate or any other aspect of this collection of information, including suggestions for reducing this burden, to Washington headquarters Services, Directorate for Information Operations and Reports, 1215 Jefferson Davis Highway, Suite 1204, Arlington, VA 22202-4302, and to the Office of Management and Budget, Paperwork Reduction Project (0704-0188) Washington, DC 20503. 1. AGENCY USE ONLY 2. REPORT DATE 3. REPORT TYPE AND DATES COVERED (Leave blank) March 2016 Master’s thesis 4. TITLE AND SUBTITLE 5. FUNDING NUMBERS PROTOTYPE DESIGN AND MISSION ANALYSIS FOR A SMALL SATELLITE EXPLOITING ENVIRONMENTAL DISTURBANCES FOR ATTITUDE STABILIZATION 6. AUTHOR(S) Halis C. Polat 7. PERFORMING ORGANIZATION NAME(S) AND ADDRESS(ES) 8. PERFORMING Naval Postgraduate School ORGANIZATION REPORT Monterey, CA 93943-5000 NUMBER 9.
    [Show full text]
  • Space Security Index 2013
    SPACE SECURITY INDEX 2013 www.spacesecurity.org 10th Edition SPACE SECURITY INDEX 2013 SPACESECURITY.ORG iii Library and Archives Canada Cataloguing in Publications Data Space Security Index 2013 ISBN: 978-1-927802-05-2 FOR PDF version use this © 2013 SPACESECURITY.ORG ISBN: 978-1-927802-05-2 Edited by Cesar Jaramillo Design and layout by Creative Services, University of Waterloo, Waterloo, Ontario, Canada Cover image: Soyuz TMA-07M Spacecraft ISS034-E-010181 (21 Dec. 2012) As the International Space Station and Soyuz TMA-07M spacecraft were making their relative approaches on Dec. 21, one of the Expedition 34 crew members on the orbital outpost captured this photo of the Soyuz. Credit: NASA. Printed in Canada Printer: Pandora Print Shop, Kitchener, Ontario First published October 2013 Please direct enquiries to: Cesar Jaramillo Project Ploughshares 57 Erb Street West Waterloo, Ontario N2L 6C2 Canada Telephone: 519-888-6541, ext. 7708 Fax: 519-888-0018 Email: [email protected] Governance Group Julie Crôteau Foreign Aairs and International Trade Canada Peter Hays Eisenhower Center for Space and Defense Studies Ram Jakhu Institute of Air and Space Law, McGill University Ajey Lele Institute for Defence Studies and Analyses Paul Meyer The Simons Foundation John Siebert Project Ploughshares Ray Williamson Secure World Foundation Advisory Board Richard DalBello Intelsat General Corporation Theresa Hitchens United Nations Institute for Disarmament Research John Logsdon The George Washington University Lucy Stojak HEC Montréal Project Manager Cesar Jaramillo Project Ploughshares Table of Contents TABLE OF CONTENTS TABLE PAGE 1 Acronyms and Abbreviations PAGE 5 Introduction PAGE 9 Acknowledgements PAGE 10 Executive Summary PAGE 23 Theme 1: Condition of the space environment: This theme examines the security and sustainability of the space environment, with an emphasis on space debris; the potential threats posed by near-Earth objects; the allocation of scarce space resources; and the ability to detect, track, identify, and catalog objects in outer space.
    [Show full text]